Ludwig Institute for Cancer Research, Victoria 3050, Australia.
J Immunol. 2011 Jun 15;186(12):7164-75. doi: 10.4049/jimmunol.1004185. Epub 2011 May 13.
Alternatively activated M2 macrophages are implicated as both regulators and agents of lung disease, but their control is poorly understood. SHIP-1 is a 5' inositol phosphatase that negatively regulates the PI3K signaling pathway implicated in inflammation. SHIP-1-deficient mice have defects in hematopoiesis and B cell development, and die prematurely due to consolidation of lungs with M2-skewed macrophages. SHIP-1 is thought to restrain M2 macrophage polarization, with deregulated M2 skewing coinciding with severe lung disease in SHIP-1-deficient mice. To determine the influence of genetic background on the lung phenotype in SHIP-1(-/-) mice, we backcrossed the SHIP-1 null mutation onto C57BL/6 (Th2-resistant) and BALB/c (Th2-prone) backgrounds. Remarkably, we found that inflammatory lung disease was severe in C57.SHIP-1(-/-) mice, but absent in BALB.SHIP-1(-/-) mice. C57.SHIP-1(-/-), but not BALB.SHIP-1(-/-) mice had greatly increased myeloid progenitors, myeloid hyperplasia, markedly enhanced numbers of activated alveolar macrophages, and elevated amounts of Th2 and proinflammatory cytokines in bronchoalveolar lavage fluid and serum, suggesting that deregulated cytokine production induced disease. C57.SHIP-1(-/-) mice also developed severe B cell-dependent autoimmune disease, which was markedly attenuated on the BALB/c background. These data demonstrate that, contrary to current concepts, loss of SHIP-1 alone is not sufficient to cause lung inflammation, with disease only manifest on a permissive genetic background. This finding questions the nature of the lung disease in SHIP-1(-/-) mice, suggesting that its M2 classification is not strictly correct. Future identification of disease-promoting loci might reveal determinants of comorbid lung disease and autoimmunity and uncover potentially useful therapeutic targets.
alternatively activated M2 macrophages 被认为既是肺部疾病的调节因子,也是其效应因子,但它们的调控机制尚不清楚。SHIP-1 是一种 5'肌醇磷酸酶,可负向调控参与炎症的 PI3K 信号通路。SHIP-1 缺陷小鼠在造血和 B 细胞发育方面存在缺陷,并由于肺部被 M2 极化的巨噬细胞所占据而提前死亡。SHIP-1 被认为可抑制 M2 巨噬细胞极化,M2 极化失调与 SHIP-1 缺陷小鼠的严重肺部疾病同时发生。为了确定遗传背景对 SHIP-1(-/-)小鼠肺部表型的影响,我们将 SHIP-1 缺失突变回交至 C57BL/6(Th2 抗性)和 BALB/c(Th2 易感性)背景下。令人惊讶的是,我们发现 C57.SHIP-1(-/-)小鼠的肺部炎症性疾病严重,但 BALB.SHIP-1(-/-)小鼠则不存在。C57.SHIP-1(-/-)小鼠而非 BALB.SHIP-1(-/-)小鼠的髓系前体细胞显著增加,骨髓增生明显,肺泡巨噬细胞的激活显著增加,支气管肺泡灌洗液和血清中 Th2 和促炎细胞因子的含量也显著升高,提示细胞因子失调导致疾病。C57.SHIP-1(-/-)小鼠还出现严重的 B 细胞依赖性自身免疫性疾病,在 BALB/c 背景下该疾病明显减轻。这些数据表明,与当前的概念相反,SHIP-1 的缺失本身不足以引起肺部炎症,仅在允许的遗传背景下才会发生疾病。这一发现对 SHIP-1(-/-)小鼠肺部疾病的性质提出了质疑,表明其 M2 分类并不完全正确。未来对疾病促进基因座的鉴定可能揭示肺部疾病和自身免疫的共病决定因素,并揭示潜在的治疗靶点。
